Filter medium

ABSTRACT

The invention relates to a filter medium for cleaning fluids, comprising at least one filler layer ( 9 ) which is formed from a filter material and which predetermines a preferably pleated web form of the filter medium having a longitudinal direction (X) and a transverse direction (Y), and at least one plastic grid ( 10 ) which as a support layer bears against at least one filter layer ( 9 ) and has linear elements ( 12, 14 ) which delimit through openings ( 16 ) between them. According to the invention said filter medium is characterised in that two groups of linear elements ( 12, 14 ) extend approximately at right angles to one another and delimit rectangular through openings ( 16 ), or that the linear elements ( 14 ) having a smaller diameter (d2) are in direct contact with the respective filter layer ( 9 ) of the filter medium and that the linear elements ( 12 ), which by contrast each have a larger diameter (d1) and have a greater spacing horn one another relative to the associated fillet layer ( 9 ) wine to rest on the linear elements ( 14 ).

The invention relates to a filter medium for cleaning fluids comprising at least one filter layer, formed from a filter material, which specifies a preferably pleated web form of the filter medium having a longitudinal direction and a transverse direction, and at least one plastic grid, which, as a support layer, bears against at least one filter layer and has linear elements which delimit through-openings between them, according to the embodiment of features of the preamble of independent claims 1 and 2.

Filter mediums for producing exchangeable filter elements in hydraulic systems are known in many forms and are typically comprised of a multilayer filter non-woven having a support layer on one or both exterior sides, inflow or outflow sides, of the filter non-woven. Fluid to be cleaned, for example a hydraulic fluid, flows through the filter elements, wherein there is a significant pressure difference from the inflow to the outflow sides. To be able to withstand this pressure difference and also dynamic flow forces in the unfiltered fluid, the filter mediums, from which the appropriate filter elements are manufactured, have support layers, also called support structures. The support layers undergo strong pressure changing loads during operation of the filter elements and are made from metal fabric, in particular fabric made of stainless steel wires or from plastic grids, for example.

The document EP 0 402 099 B1 discloses a reinforced textile material for use for fiber reinforced composite materials, comprising a plurality of warp threads composed of reinforced filament yarns, which extend parallel to each other in a web-like shape in the longitudinal direction of said reinforcing textile material, wherein said warp threads are disposed in the transverse direction to the said reinforced textile, in order to form a section composed of said warp threads having higher density and a section composed of said warp threads having lower density, and a plurality of weft threads composed of reinforced filament yarns, which extend parallel to each other in a web-like shape in one direction over the said warp threads, and extend diagonal to the expansion direction of the said warp threads.

With a filter medium disclosed in the document DE 10 2010 025 220 A1 a plastic grid, serving as a support structure, is formed from two groups of linear elements, which between them delimit through-openings, wherein one of the groups extends diagonally with a predetermined angle to the longitudinal and transverse direction of the web, and the other groups extend parallel to the longitudinal or transverse direction of the web. A uniform shape stability and filtration characteristic of the filter medium are attained over the surface of the plastic grid due to the grid, or respectively screen-like arrangement of the linear elements.

The document EP 1 436 062 B1 relates to a filter element for fluids having a filter material and tissue-forming support structure supporting the filter material with respect to the through flow of the filter element, at least on the cleaned side, wherein the support structure is manufactured from a plastic material and has electrically conductive elements. The support structure forms a support fabric that has both metal and plastic threads and lies flat against a filter material. The filter material and the support webs are folded in the shape of a star or pleated, wherein the metal threads extend parallel to the folds of the support web.

A filter medium of the initially named type is known for example from the document, DE 10 2008 029 443 A1. The known filter medium is formed as a type of filter web composed of a first layer support fabric, a second layer as a protective non-woven, a third layer as a main non-woven, possibly a further layer of a subsequent further protective non-woven, and in any event, a fourth layer of a another support tissue. The support webs are composed of individual plastic threads. The linear elements, composed of plastic threads forming the plastic tissue, extend diagonally to the longitudinal and transverse direction of the filter web, which is folded pleat-like into a filter element, and the spacings between the linear elements serve as free through-openings for the flow through of the fluid to be filtered.

With the exception of the plastic grid according to the document DE 10 2010 025 220 A1 in which the plastic threads or individual linear elements, securely connected together via junction locations or intersections, yield a flow-through grid structure, the other aforementioned citations refer to metal and/or plastic fabric built as linear elements composed of warp and weft threads, in which the treads or linear elements can move with respect to each other within the fabric composite material, with the consequence that the through-openings between the threads or linear elements are not constant, in particular, the through-openings can become closed due to the moved tissue composite material, which can correspondingly impair both the support properties as well as the permeability of the known tissues serving as a support layer.

Based on this prior art, the object of the invention is to further improve the support properties and permeability of a plastic grid serving as a support layer, as well as the property thereof to ding to the fitter layer to be encompassed.

This object is solved by a filter medium with the features of claim 1 and claim 2 in their respective entireties.

The filter medium according to the invention according to claim 1 is thus distinguished in that two groups of linear elements extend at nearly right angles to each other and delimit rectangular through-openings.

The individual linear elements form rectangles according to the invention, both sides of which are disposed oblique to the longitudinal and transverse direction. Due to the “tilted” rectangular structure, the filter medium according to the invention minimizes resistance for the fluids flowing through, and thus fewer turbulences and a lower pressure difference are obtained. With the folding of the filter medium into a filter element, wherein the folding occurs typically in the transverse direction, the linear elements of both groups are always ideally aligned obliquely to the corresponding fold peak, or fold valley. The arrangement according to the invention of the linear elements of the plastic grid predetermines individual channels for the fluid flowing through, such as a hydraulic fluid. All in all, the support and filtration properties of the filter medium are improved due to the geometry according to the invention of the supporting plastic grid.

The pertinent object is also achieved according to the feature arrangement of claim 2, in that the linear elements having a smaller diameter are in direct contact with the respective filter layer of the filter medium, and that the liner elements, which in contrast have a larger diameter and a greater spacing from each other than is the case with the linear element having smaller diameter, overlap the aforementioned linear elements at a distance to the associated filter layer.

Within the fixed grid structure slender threads or linear elements result, lying close to the filter layer, yielding an improved property of the plastic grid to cling to the underlying filter layer of the filter medium, which greatly improves the stability of the overall composite of the filter medium. Further, due to the cited support grid composite, the “volume giving” threads or linear elements are oriented toward the drainage side of the filter medium, with the consequence that the thread spacing or the distance between the linear element can be optimized, which again significantly improves the drainage ability of the filter medium and its permeability. Due to the arrangement of different thicknesses or diameters of the plastic grid with its fixed junction points, there is an improved adaptability of the plastic grid as a support layer to the respectively occurring fold density and filter fineness for the pleated filter medium.

With pleated filter layers, the linear elements of different diameters have proven to be particularly advantageous insofar as they can intersect with each other at an angle of 50 to 60°, preferably approximately 55°. By virtue of the non-shifting arrangement of the linear elements within the plastic grid, in this respect the through-openings for the fluid to be filtered are always held constant so that even during operation the permeability and the support properties for the support layer cannot change.

According to a particularly preferred embodiment, the distance between the linear elements having the respectively larger diameter or thickness, as seen in the longitudinal alignment of a respective filter fold of the pleated filter layer, amounts to approximately 8 times to 12 times, preferably 10 times the distance between the linear elements having the respectively smaller diameter or the respectively smaller thickness.

When reference is made in the following to the thickness or the diameter of the linear elements, the diameter specification basically relates to the cylindrical threads as a linear element, seen in cross-section, or respectively, the thickness specification is based on the largest edge length or view side of a thread cross-section shaped, for example, as a rectangle (also a square) or oval, as seen in cross-section. In this respect, the specification of the diameter or the thickness can be understood as being synonymous in the following description of the invention. Additionally, within the plastic grid, the linear elements of one group can have, in increments, several differing, small diameters or thicknesses, whereas the linear elements of the other group, having larger diameters, can be dimensioned differently for this purpose, also in increments with respect to the cross-section ratios.

The linear elements of one group are each advantageously disposed equidistant to each other, i.e., having the same linear spacing. This results in the advantage that uniform sized through-openings are determined by the plastic grid, and thus, uniform support and filtration properties are attained over the surface of the plastic grid. The through-openings preferably have side lengths in the range of 900 μm to 3000 μm, in particular, a first side length of approximately 915 μm and a second side length of approximately 2908 μm.

The linear elements of the plastic grid can delimit square through-openings, in other words, the first side length and the second side length of the respective through-opening can be selected to be equal. This design of the filter medium according to the invention results in a particularly good combination of support and filtration properties. The linear elements can extend obliquely to the longitudinal and transverse direction at an angle of 45° in flat mat webs such that there is no preferred direction. Typically however, different angles are selected for the oblique setting with respect to the longitudinal and transverse direction, thereby thusly attaining a use-optimized fluid passage.

The thickness of the linear elements can vary, in particular wherein the linear elements of the first group have a thickness that is different from the linear elements of the second group. The passage area that fluid can flow through, defined by the through-openings, is further enlarged due to the use of linear elements with different thicknesses. The strength, and consequently the support property, of the plastic grid is determined by the design, in particular the material and the thickness, of the linear elements. The linear elements preferably have a thickness in the range of 300 μm to 450 μm, wherein the linear elements of the first group in particular have a thickness of approximately 419 μm and the linear elements of the second group have a thickness of approximately 330 μm.

The shape stability and filtration characteristics of the filter medium are set according to need by means of the grid, or screen-shaped, arrangement of the linear elements. The linear elements of the plastic grid can have a thread-like shape. Additionally, at least one electrically conductive linear element can be embedded in the plastic grid, wherein the electrically conductive element is preferably formed free of metal and/or contains carbon. It is particularly preferred to form the respective electrically conductive linear element as a bicomponent fiber having a plastic fiber coated with carbon.

The material of the plastic grid comprises in a preferred manner, polybutylene terephthalate (PBT), polypropylene (PP) and/or polyethylene (PE) plastic. Such plastic materials are characterized by medium strength and a high rigidity and hardness. Semi-crystalline polyethylene terephthalates have thermal limitations of use at −20° C. and +100° C., momentarily up to +200° C. They are resistant to diluted acids, aliphatic and aromatic hydrocarbons, oils, fats, esters and alcohols, Polybutylene terephthalate, comparison to polyethylene terephthalate, has a somewhat lower stability, its limitations lie at approximately −40° C. and +250° C. Isotactic polypropylene can be used up to approximately +150° C. and has proven to be very chemically stable.

Further advantages and features of the invention arise from the further claims, the figures and the following description of the drawings. The aforementioned and further described features can be implemented in any combination in a filter medium according to the invention. It is understood that the features shown in the figures are depicted purely schematically and are not to scale. The figures show in:

FIG. 1 a top view of a section of a plastic grid of a filter medium known from the prior art;

FIG. 2 a top view of a section of a plastic grid of a filter medium according to the invention with filter layers disposed below;

FIG. 3 a view of a part of the now pleated filter medium according to FIG. 2; and

FIG. 4 a perspective representation of an assembly line for producing the plastic grid configured according to the invention.

FIG. 1 shows a top view of a section of a plastic grid 10 according to the prior art. The plastic grid 10 has substantially the shape of a web with a first group of the first linear elements 12 and a second group of second linear elements 14. The first linear elements 12 extend equidistant, parallel to each other, and are disposed diagonal to the longitudinal direction X, at a first angle α1, and diagonal to the transverse direction Y, at a further first angle β1. Correspondingly, the second linear elements 14 extend parallel to each other and diagonal to both directions X, Y at second angles α2, β2.

The linear elements 12, 14 delimit through-openings 16 between each other, which are formed substantially uniformly, each having a diamond shape with a first diagonal having a length of L=2431.8 μm and a second diagonal with a length of Q=1273 μm. The diamond structure of the diamond-shaped through-openings 16 is predetermined by the arrangement of the two groups of first and second linear elements 12, 14. With a further processing of the plastic grid 10, the longitudinal direction X specifies a direction for the intake into a folding machine.

The first linear elements 12 have substantially the same thickness d₁=298 μm, correspondingly the second linear elements 14 have a thickness d₂=292 μm. in the representation of FIG. 1, the first linear elements 12 bear against the second linear elements 14, and are securely connected to them at intersections 18, in other words fixed to them. However, it is also conceivable to form the linear elements 12, 14 to obtain the plastic grid 10 as a whole, integrally from a plastic material. The two groups of linear elements 12, 14 are disposed obliquely to each other, and form an acute angle in the longitudinal direction X, the sum of the two angles being α2+α1<90°, and in the transverse direction Y form an obtuse angle, the sum of the further angles being β1+β2 >90°. It is understood that the two groups of the linear elements 12, 14 can be oriented to each other in such a manner that an obtuse angle is formed in the longitudinal direction X and an acute and is formed in the transverse direction Y.

In contrast, FIG. 2 shows a design of the plastic grid 10 according to the invention with the special feature that the two groups of the linear elements 12, 14 are oriented at right angles to each other. Consequently, the angles α1 to β2, at which the linear elements 12, 14 intersect each other in the longitudinal direction X and the transverse direction Y, in other words, the angles at which they are placed diagonally to each other, are to be selected such that the angles α1 to β2 assigned to the respective directions X, Y add up to 90°, α1+α2=90° and β1=90°. In the example embodiment shown in in FIG. 2, the thickness d₁ of the first linear element 12 is d₁=419 μm and the thickness d₂ of the second linear elements 14 is d₂330 μm. The linear elements 12, 14 of the respective groups are disposed equidistant, parallel to each other, such that uniform through-openings 16 are specified, having a first side length a=2988 μm specified by the spacing of the first linear element 12, and a second side length b=915 μm specified by the spacing of the second linear elements 14. The dimension a x b of the rectangular through-openings 16 defines the surface available for fluid flow through, and consequently the fluid permeability of the plastic grid 10.

As shown particularly in FIG. 3, which relates to a pleated filter layer 9, which shows however only parts of individual filter folds 11 of the star-shaped folded or pleated filter medium formed into a type of hollow cylinder of the filter element (not shown), the relevant outer filter layer 9 is surrounded or enveloped by the plastic grid 10 shown two-dimensionally in FIG. 2. The individual filter folds 11 bulge out therefore in a known manner towards the observer of FIG. 3 in mountain bulges, wherein respectively adjacent filter folds 11 are connected together in the valley floors, likewise in curve-shaped profiles.

The linear elements 14 having the respectively smaller diameter d₂ are in direct contact with the respective top side of the filter layer 9 of the filter medium, pleated to this extent. In contrast, the linear elements 12 having respectively a larger diameter d₁, having a greater spacing from each other, are disposed over the linear elements 14 with the smaller diameter d₁[Sic: should be d₂]. In this respect, the linear elements 14 have a greater spacing compared the associated adjacent filter layer 9, and are held via the linear elements 14 at a distance to the filter layer 9. Seen in the inflow direction of the filter material and thus toward the filter layer 9, the thin threads, or the linear elements 14, lying closely together, form an ideal support and protection for the sensitive filter layer 9. In contrast, in the outflow direction, the threads 12, providing volume, form large flow cross-sections at an optimal distance with respect to the filter layer 9, with the consequence that only minimal flow resistances form, such that a type of optimized drainage layer is attained via the support grid 10.

If the filter layer 9 is pleated, in accordance with to the depiction according to FIG. 3, the linear elements 12, 14 of different diameters intersect and enclose between them an imaginary angle δ of 50 to 60°, preferably of approximately 55°. Furthermore, it is provided that the distance c₁ between the linear elements 12 with the respectively larger diameter d₁, seen in the longitudinal direction LX on the top side of a respective filter fold 11 of the pleated filter layer 9, is approximately 8- to 12-times, preferably approximately 10-times the distance c₂ between the linear elements 14 having the respectively smaller diameter d₂. Thus, with the concrete example embodiment, the distance c₁ according to the second side length b is approximately 2908 μm and the distance c₂ according to the first side length a is approximately 915 μm.

As further illustrated in FIGS. 2 and 3, as seen in the viewing direction of FIGS. 2 and 3, the linear elements 12 having the greater thickness d₁ are disposed over the linear elements 14 having the smaller thickness d₂. If said support grid 10, forming the pleated filter mat, shown in more detail in FIG. 3, is now placed in folds 11, the thicker linear elements 12 lie on top of each other between the adjacent folds 11, wherein uniform locations of abutment form, such that the underlying thin linear elements 14 are then correspondingly distanced from each other by the double thickness or width of the linear elements 12. This way, a conductive or drainage channel arises within the respective folds 11, which allows the guidance of fluid, relatively free of resistance, within the pleated filter medium. As further shown in FIG. 2, depending on the production method, particularly at the junction or intersection locations 15 of thick linear elements 12 with the thin linear elements 14, at every location of an intersection point 15 or undercut, the subsequent section of a linear element 14 is offset to the preceding linear element part by a predetermined distance or offset 17, with the consequence that again, in the pleated structure of the filter medium, the rectangular through locations 16 between the individual folds substantially lie on top of each other, such that also in this respect an undisturbed fluid passage is attained through the then adjacent filtering filter material.

Instead of the rectangular through locations 16, square through locations 16 can also be obtained from the plastic grid 10, if every second linear element 14 with the smaller diameter d₂ can be appropriately dispensed with. The offset shown in FIG. 2, at the offset location 17 can also be omitted such that all linear elements 14 are disposed parallel to each other and likewise as with the linear elements 12 within the grid structure 10.

A method is sketched out in FIG. 4 for producing the plastic grid 10. Plastic granulate is supplied into an extruder 20, and liquefied there. The liquefied granulate, using a spiral 24, at a discharge 26, at the end of which nozzles, not shown, are located, disposed on rings rotating in opposite directions. Upon passing through the nozzles rotating in or counter to a direction of rotation 28, a hose 30 arises from the liquefied plastic granulate. For cooling, the extruded hose 30 is guided over a deflection roller 32 a through a water bath 34.

After a further deflection roller 32 b, a longitudinal stretching 38 is performed in the longitudinal direction X of a web 36. The hose 30 further passes through a cutting device 40 and is cut by this in the longitudinal direction X so that the web 36 is obtained. Via further rollers 42 a, 42 b, and 42 c, which are formed as calender or deflection rollers, the longitudinally stretched web 36 is guided to an arrangement of lateral guide elements 44 a to 44 d, where a transverse stretching 46 is performed in the transverse direction Y. Parallel thereto, edges are formed on the web 36. The longitudinal stretching 38 and the transverse stretching 46 are selected and performed according to the grid structure to be formed in the web 36, such as the size of the rectangle, setting the diagonal of the groups of linear elements 12, 14 to the longitudinal direction X and the transverse direction Y.

When performing the longitudinal and transverse stretching 38, 46, the plastic material is still not completely hardened, and the web 36 is consequently still highly flexible. The final hardening of the plastic material takes place after the transverse stretching 46. The finished plastic grid 10 is rolled up onto a web roller 48 for storing and/or for transport, and is cut through or separated in the transverse direction Y corresponding to the lengths of the web 36 to be rolled onto the web roller 48. Instead of the web roller 48, a device for connecting the plastic web 10 to a filter layer of the filter medium and/or a folding machine for the filter medium can be adjoined thereto. 

1. A filter medium for cleaning fluids, comprising: at least one filter layer (9) formed from a filter material that specifies a preferably pleated web of the filter medium having a longitudinal direction (X) and a transverse direction (Y), and at least one plastic grid (10), that bears against at least one filter layer (9) as a support layer and has linear elements (12, 14), which extend in groups parallel to each other and at a predetermined angle diagonal to the longitudinal direction (X) and to the transverse direction (Y) of the filter medium, and which delimit through-openings {16) between each other, characterized in that two groups of linear elements {12, 14) extend at nearly right angles to each other and delimit rectangular through-openings (16).
 2. A filter medium for cleaning fluids, comprising: at least one layer (9) formed from a filter material, which defines a preferably pleated web form of the filter medium having a longitudinal direction (X) and a transverse direction (Y), and at least one plastic grid {10), which bears against at least one filter layer (9) as a support layer and has linear elements (12, 14), which, connected together, delimit through-openings (16), characterized in that the linear elements (14) having a smaller diameter (d₂) are in direct contact with the respective filter layer (9) of the filter medium, and that the linear elements (12), in contrast, each having a larger diameter (d₁) and having a greater spacing from each other than is the case with the linear elements (14) having smaller diameter (d₂), overlap said linear elements (14) at a spacing to the associated filter layer (9).
 3. The filter medium according to claim 1, characterized in that with the pleated filter layer (9), the linear elements (12, 14) of different diameters (d₁, d₂), insofar as they intersect, form an angle of 50 to 60°, preferably of approximately 55°.
 4. The filter medium according to claim 1, characterized in that the distance (c₁), seen in the longitudinal alignment (LX) of a respective filter fold (11) of the pleated filter layer (9), between the linear elements (12) having the respectively larger diameters (d₁) is approximately 8 to 12 times, preferably about 10 times, the distance (c₂) between the linear elements (14) having the respectively smaller diameter (d₂).
 5. The filter medium according to claim 1, characterized in that the through-openings (16) have a side lengths (a, b) in the range of 900 μm to 3000 μm, in particular a first side length (a) of 915 μm and a second side length (b) of approximately 2908 μm.
 6. The filter medium according to claim 1, characterized in that the linear elements (12, 14) of the plastic grid (10) delimit square-openings (16).
 7. The filter medium according to claim 1, characterized in that the thicknesses or the diameters (d₁, d₂) of the linear elements (12, 14) vary, preferably that the linear elements of the first group (12) have a different thickness or diameter (d₁) than the linear elements of the second group (14).
 8. The filter medium according to claim 1, characterized in that the linear elements (12, 14) have a diameter (d₁,d₂) in the range of 300 μm two 450 μm, preferably that the linear elements of the first group (12) have a diameter (d1) of approximately 419 μm and the linear elements of the second group (14) have a diameter (d₂) of approximately 330 μm.
 9. The filter medium according to claim 1, characterized in that the material of the plastic grid (10) comprises polybutylene terephthalate (PBT), polypropylene (PP) and/or polyethylene (PE) plastic.
 10. The filter medium according claim 1, characterized in that the linear elements of the first group (12) with the linear elements of the second group (14) form fixed junctions (15) at the intersection locations of the grid (10), at which the linear elements are held in their layer, stationary in relation to each other.
 11. The filter medium according to claim 1, characterized in that the linear elements (14) having a smaller diameter (d₂) have, at the respective junctions (15), an offset location (17) and that the offset at this offset location (17) corresponds approximately to the smaller diameter (d₂) of the linear element (14). 